Freezing system for electronic mobile device repair

ABSTRACT

A system utilized for freezing parts of electronic mobile devices comprises a freezing machine incorporating internet communication hardware and software, molds and vacuum bags and a central computer server hosting and operating a web-centric and/or mobile app software application which connects to, updates and operates the freezing machine via the Internet. The freezing machine comprises a housing, an engine with cylindrical cooling head, an adjustable cooling head ring fixture and metal plate attached to the adjustable cooling head ring fixture. The freezing machine further comprises an encapsulation chamber, a lid, a power inlet, a LCD/OLED display and a PCB with processor capable of operating the freezing machine.

RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No.17/013,490, filed on Sep. 4, 2020, which claims the benefit of U.S.Provisional Application No. 62/897,183, filed on Sep. 6, 2019, thecontent of which are incorporated herein by reference.

BACKGROUND

Mobile electronic devices such as (but not limited to) tablets, mobilephones, mobile smart phones and gaming devices have become increasinglypopular and also increasingly smaller. The various components and partsof such mobile electronic devices (displays, printed circuit boards,central processing units, “system on a chip”, batteries, chipsets,antenna, modules, microphones, crystal oscillators, filters, rom memory,ram memory, power IC (integrated circuit), charging IC, logic IC, audioIC, microphones, camera lenses, sensors) have become and are becomingincreasingly small and are assembled together in increasingly smallerform factors so that the mobile electronic device can have attractiveand competitive features, specifications and dimensions. Furthermore thedesigners, engineers and producers of mobile electronic devices haveresorted to combining the aforesaid components/parts into single unitcomponents/parts.

In the event that a component/part of a mobile electronic device isdamaged (either because the mobile electronic device was dropped, hit,submerged in water, overheated, etc., or either due to thecomponent/part being defective or becoming damaged due to prolonged use)it is extremely difficult to isolate the damaged component/part forrepair or replacement as many components/parts are stuck together withspecial bonding glue or material or are so tightly assembled and puttogether that conventional methods of isolation are not effective. Thismakes the repair or replacement of the damaged component/part in somecases impossible, resulting in the repair of the electronic mobiledevice only being possible if larger components containing the damagedcomponent/part are replaced. This is extremely costly and sometimes thecost of same exceeds the value of the electronic mobile device resultingin the customer having to purchase a new mobile electronic device.

Freezers for freezing electronic mobile device screens for repairpurposes are also known in the art. However these freezers have severalshortcomings. For example, such freezers do not have internetcommunication hardware and software allowing them to connect to acentral server via the internet facilitating the sending and receivingof instructions and data to and from the freezer and a central server;the freezers cannot, on a remote basis, receive instructions, data andfreezing parameters (temperatures, timing) specific to a particularmobile device screen from a central server via the internet (on sitephysical instruction and data input and updates are required); thefreezers have software and freezing parameters which cannot be updatedremotely via the internet (on site physical updates are required); thefreezers cannot reach low enough temperatures needed for efficientfreezing resulting in poor performance; the freezers are very large,taking up as much space as a large chest freezer; the freezers areunsafe as the freezers use ammonia or nitrogen or other dangeroussubstances to reach freezing temperatures; the freezers consume largeamounts of power; and the freezers have to be kept running all day.

SUMMARY

A system is provided comprising a central freezing machine which alsoincorporates internet communication hardware and software, molds andvacuum bags and a central computer server hosting and operating aweb-centric and/or mobile app software application which connects to thecentral freezing machine via the internet. The system:

A. is small enough to be placed on a small bench or desk requiring verylittle space to operate;

B. consumes very small amounts of power;

C. reaches extremely low sub-zero temperatures;

D. does not need to be kept running all day and can reach extremely lowsub-zero temperatures fast and with low power consumption;

E. can efficiently freeze and isolate the aforesaid electronic mobiledevice components/parts so that the components/parts can be repaired orreplaced resulting in a successful and cost-efficient repair of theelectronic mobile device;

F. performs real time remote sending and receiving of instructions,freezing parameters (temperature, time) and data specific to aparticular mobile device and/or mobile device component/part to and fromthe central freezing machine and the central server via the internet;

G. performs real time sending and receiving of data between the centralfreezing machine and the central server via the internet facilitatingupdates to the software of the central freezing machine so as toaccommodate the efficient and correct freezing of new electronic mobiledevice components/parts, to rectify operating defects of the centralfreezing machine, to improve the central freezing machine efficiency andfunctionality as well as to add additional central freezing machinefunctionality; and

H. includes a real time web-centric or mobile app based softwareplatform and database allowing remote control of the central freezingmachine as well as remote access to real time and historic repair andcentral freezing machine operating related data.

In one aspect of the technology, a system for freezing components/partsof electronic mobile devices so that the components/parts can beisolated and repaired or replaced, is disclosed.

The system comprises a central freezing machine incorporating internetcommunication hardware and software, molds and vacuum bags with specificdimensions for various models of electronic mobile devices and a centralcomputer server hosting a web-centric and/or mobile app softwareapplication which connects to, communicates with, exchanges data,updates software and operates the central freezing machine via theInternet and also provides real time and historical operational data ofthe central freezing machine.

In one aspect, the central freezing machine is comprised of six panelswhich are held together by four internal metal columns and screwsforming the central freezing machine housing. In one aspect the centralfreezing machine contains one or more of the following components andfeatures. In one aspect the central freezing machine contains a Stirlingengine which is utilized to generate sub-zero temperatures and which ismounted on the bottom base panel of the central freezing machine housingin a manner in which the Stirling engine faces in an upwards direction.In one aspect the Stirling engine has a top end cylindrical cooling headwhich reaches sub-zero temperatures when the Stirling engine is inoperation. In one aspect an adjustable cooling head ring fixture isaffixed around the cylindrical cooling head and attached to suchadjustable cooling head ring fixture is a metal plate so that thesub-zero temperatures of the cylindrical cooling head are transferred tothe adjustable cooling head ring fixture and to the metal plateresulting in the metal plate reaching sub-zero temperatures andoperating as a base upon which the electronic mobile devicecomponents/parts are placed in order to be frozen.

In one aspect the central freezing machine further comprises anencapsulation chamber made of a combination of polyurethane and expandedpolypropylene material and parts which encapsulates the cylindricalcooling head, the adjustable cooling head ring fixture and the metalplate for temperature and air insulation purposes and also to form afreezing chamber with the metal plate being the base of the chamber. Inone aspect, screwed at the top of the freezing chamber is the topcentral freezing machine housing panel.

In one aspect the freezing chamber is sealed by a push down lidcomprised of a metal top layer and subsequent layers of polyurethanesponge and expanded polypropylene so that when the push down lid ispushed into the freezing chamber the push down lid has a spring spongeeffect allowing the push down lid to press gently and firmly on theelectronic mobile device part which has been placed in the freezingchamber and on to the metal plate. In one aspect there are 4 clips onthe metal top layer of the lid which allow the lid to close when pusheddown, and when pushed down again to pop open.

In one aspect, a screw down adjustable lever system is found just abovethe metal plate and is utilized to keep the electronic mobile devicepart firmly pressed against the metal base so as to lessen the freezingperiod, ensure uniform freezing and also to maximize the freezingefficiency.

The central freezing machine also comprises a control printed circuitboard with processor and operating system software capable of operatingthe central machine as well as establishing a two way datacommunications connection with the central computer server via a two-waydata Internet connection obtained and provided through a communicationsprinted circuit board and Wi-Fi aerial and/or Ethernet port housedwithin the central freezing machine. In one aspect, the central freezingmachine unit may also comprise a LCD display (liquid crystal display) orOLED display (organic light-emitting diode) display for operationcontrol and display purposes.

In one aspect the central freezing machine contains a power inlet foundat the bottom back base of the central freezing machine and which servesthe purpose of distributing power to the various components of thecentral freezing machine, namely the Stirling engine, the control PCB(printed circuit board) and the communications PCB. In one aspect amechanical on/off switch is also found at the bottom back base of thecentral freezing machine and is utilized to power the central machineunit in an on or off power position.

In one aspect the system may also contain a central computer serverhosting and operating a web-centric and/or a mobile app softwareapplication used for remotely operating the central freezing machine viathe Internet and/or remotely updating the central freezing machinesoftware and settings via the Internet and also for providing real timeand historical central freezing machine operating data to the user ofthe system whereby the owner of one or multiple central freezingmachines can either remotely update one or more central freezing machinesoftware and settings and/or remotely control the operation of one ormore central freezing machines and/or remotely activate and de-activateone or more central freezing machines and/or have immediate remoteaccess to real time or historical statistical information related to therepairs done by such machines, repairs per electronic mobile devicemodel, repairs per technician, repairs per time period, repairs perlocation, repairs per grouped electronic mobile device models,technicians, time periods and locations, repair success rates, repairtimes, electronic mobile device models repaired, technician identity,defects of the machine, wrong machine settings, user identified machinedefaults, consumables and parts required and being able to order suchconsumables and parts immediately via the web-centric and/or a mobileapp software application.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1A is a view of the central freezing machine with one or moreaspects of the technology.

FIG. 1B is an alternate view of the central freezing machine showing oneor more aspects of the technology.

FIG. 1C is a top front view of the central freezing machine showing thetop lid, the front panel with LCD or OLED display and operation buttonas well as the top panel and left side panel.

FIG. 1D is a front view of the central freezing machine specificallyshowing the front, left side and right side panels, the LCD or OLEDdisplay, the operation button and the handle of the top lid.

FIG. 1E is a front top view of the central freezing machine specificallyshowing the front, left side and right side panels, the LCD or OLEDdisplay, the operation button, the top panel, the freezing chamber andthe top lid in a suspended state showing how the top lid lifts out ofthe freezing chamber.

FIG. 1F is a front view of the central freezing machine specificallyshowing the front, left side and right side panels, the LCD or OLEDdisplay, the operation button, and the top lid in a suspended stateabove the central freezing machine.

FIG. 1G is a back view of the central freezing machine showing the back,left side and right side panels, the ON/OFF power switch, the antenna,the WPS (Wi-Fi Protected Setup) switch, the Ethernet inlet port, the USB(universal serial bus) inlet port and the power inlet.

FIG. 1H is a back top view of the central freezing machine showing theback, left side and right side panels, the ON/OFF power switch, theantenna, the Ethernet inlet port, the USB inlet port, the power inlet,the freezing chamber and the top panel.

FIG. 2A is a top view of the adjustable cooling head ring fixture andthe metal plate.

FIG. 2B is a top view of the adjustable cooling head ring fixture andthe metal plate specifically showing how the adjustable cooling headring fixture and the metal plate are attached together.

FIG. 2C is a side view of the adjustable cooling head ring fixture andthe metal plate when the adjustable cooling head ring fixture and themetal plate are attached together.

FIG. 2D is a side view of the Stirling engine, the Stirling engine topend cylindrical cooling head and the cooling head ring fixture and metalplate attached together and affixed to the Stirling engine top endcylindrical cooling head.

FIG. 2E is a side view of the Stirling engine, the Stirling engine topend cylindrical cooling head and the cooling head ring fixture and metalplate attached together and affixed to the Stirling engine top endcylindrical cooling head.

FIG. 2F is a side view of the Stirling engine, the Stirling engine topend cylindrical cooling head and the cooling head ring fixture and metalplate attached together and affixed to the Stirling engine top endcylindrical cooling head and specifically shows how the encapsulationchamber made of a combination of polyurethane and expanded polypropylenematerial and parts encapsulates the cylindrical cooling head, theadjustable cooling head ring fixture and the metal plate for temperatureand air insulation purposes and also to form a freezing chamber.

FIG. 2G is a top side view of the freezing chamber, the encapsulationchamber and the Stirling engine.

FIG. 2H is an alternate top side view of the freezing chamber, theencapsulation chamber and the Stirling engine.

FIG. 2I is a side view of the bottom panel, the metal columns, theStirling engine, the encapsulation chamber and the push down lidcomprised of a metal top layer and subsequent layers of polyurethanesponge and expanded polypropylene.

FIG. 3A is a top view showing the freezing chamber, the metal plate, thetop panel, the 4 screws which attach the metal plate to the adjustablecooling head ring fixture, the left, right, back and front panels, theantenna and two adjustable lever systems.

FIG. 3B is a top angled view showing the metal plate, the two adjustablelever systems and how the two adjustable lever systems are inserted onthe metal plate and a mobile phone which is being pressed on to themetal plate by the two adjustable lever systems.

FIG. 3C is a top view showing the metal plate, the two adjustable leversystems and how the two adjustable lever systems are inserted on themetal plate and a mobile phone which is being pressed on to the metalplate by the two adjustable lever systems.

FIG. 3D is a side view showing the metal plate, two adjustable leversystems and how the two adjustable lever systems are inserted on themetal plate and a mobile phone which is being pressed on to the metalplate by the two adjustable lever systems.

DETAILED DESCRIPTION

The technology may be best understood by reference to the followingdescription taken in conjunction with the accompanying representations.

Turning now to FIGS. 1A through 1H, various views of the centralfreezing machine 30 in accordance with one or more aspects of thepresent technology are shown. A back housing panel 2, a front housingpanel 1, a bottom housing panel 5, a left side panel 3, a right sidepanel 4 and a top housing panel 6 are shown. The four corners of the tophousing panel 6 are screwed onto the top end of four steel columns 7,whilst the bottom end of the four steel columns 7 is screwed onto thefour corners of the bottom housing panel 5. The front housing panel 1,the back housing panel 2, the side left panel 3, the right side panel 4are then clipped or screwed onto the 4 steel columns 7 resulting in theformation of the housing of the central freezing machine.

Within the housing of the central freezing machine 30, a Stirling enginesystem complete with built in PCB, power supply unit and cooling fan 8is also shown which is mounted and screwed to the bottom housing panel5. The Stirling engine system 8 is mounted and screwed to the bottomhousing panel 5 in a manner in which the Stirling engine faces in anupwards direction. The Stirling engine system 8 is utilized to generatesub-zero temperatures which may even exceed negative 100 degreesCelsius. The Stirling engine system 8 has a top end cylindrical coolinghead which reaches sub-zero temperatures which may even exceed negative150 degrees Celsius and which vary depending on the voltage and currentdirected to the Stirling engine system 8. An adjustable cooling headring fixture 9 is affixed around the Stirling engine 8 cylindricalcooling head and attached to such adjustable cooling head ring fixture 9is a metal plate 10 so that the sub-zero temperatures of the Stirlingengine 8 cylindrical cooling head are transferred to the adjustablecooling head ring fixture 9 and to the metal plate 10 resulting in themetal plate 10 reaching sub-zero temperatures and operating as a baseupon which the electronic mobile device components/parts are placed inorder to be frozen. Persons having skill in the art will realize thatthe adjustable cooling head ring fixture 9 and the metal plate 10 can bemade out of copper and/or aluminum or any other metal or material whichcan be deemed to be the best option for strength and temperaturetransfer from the Stirling engine 8 top end cylindrical cooling head tothe adjustable cooling head ring fixture 9 and to the metal plate 10.

An encapsulation chamber 12 is also shown. The encapsulation chamber 12is comprised of a combination of polyurethane and expanded polypropylenematerial and parts which are necessary to maintain air and temperatureinsulation efficiency and strength. Furthermore the encapsulationchamber 12 also comprises internal polyurethane and expandedpolypropylene parts 11 which also give strength and maximize vibrationabsorption. Persons having skill in the art will realize that thematerial utilized for the composition of the encapsulation chamber 12may vary depending on temperature, air, vibration absorption andstrength requirements. The encapsulation chamber 12 encapsulates theStirling engine 8 top end cylindrical cooling head, the adjustablecooling head ring fixture 9 and the metal plate 10 for temperature andair insulation purposes and for strength and vibration purposes and alsoto form a freezing chamber 31 with the metal plate 10 being the base ofthe freezing chamber 31. The freezing chamber 31 walls are further linedand strengthened by the freezing chamber wall perimeter 13.

A push down lid 14 is also shown. The push down lid 14 is comprised of 5layers, namely the top push down lid aluminum layer 14, the secondexpanded polypropylene layer 15 for strength purposes, the third spongepolyurethane layer 16 for a sponge spring effect, the fourthpolyurethane layer 17 for structural effect and the fifth expandedpolypropylene layer 18 for strength effect. The overall functioning ofthe push down lid 14 is not only to seal the freezing chamber but alsoto have a sponge spring open and close feature allowing the push downlid 14 to press gently and firmly on the electronic mobile device partwhich has been placed in the freezing chamber 31 and on to the metalplate 10. Furthermore four push down clips are found on the top pushdown lid 14 layer which allow the push down lid 14 to close when pusheddown, and when pushed down again to pop open. Persons having skill inthe art will realize that number of layers and material utilized for thecomposition of the push down lid 14 as well as the quantity of push downclips may vary depending on temperature, air, vibration absorption andstrength requirements.

A control PCB (printed circuit board) 27 is also shown. Persons havingskill in the art will realize that the control PCB 27 can be situated indifferent areas within the central freezing machine 30. The control PCB27 has a processor and software which make the control PCB 27 capable ofoperating the central freezing machine 30 and the Stirling engine system8 and also at variable user required temperatures. The control PCB 27 isalso capable of establishing and performing two-way Internet datacommunication with the central computer server 32 (which hosts andoperates a web-centric and/or mobile app software application) obtainedand provided through a communications PCB 28 facilitating real time,remote sending and receiving of operating and process instructions,freezing parameters (temperature, time) and data specific to aparticular mobile device and/or mobile device component/part. TheInternet two-way data communication between the control PCB 27 and thecentral computer server 32 (which hosts and operates a web-centricand/or mobile app software application) facilitates and enables thetransmission by a user of the web-centric and/or mobile app softwareapplication hosted on the central computer server 32 of operating andprocess instructions and data specific to a particular mobile deviceand/or mobile device component/part to the control PCB 27 in order tocontrol the operations of the central freezing machine 30 and Stirlingengine system 8 as well as facilitating updates to the software of thecentral freezing machine 30 so as to accommodate the efficient andcorrect freezing of new electronic mobile device components/parts, torectify operating defects of the central freezing machine 30, to improvethe central freezing machine 30 efficiency and functionality as well asto add additional central freezing machine 30 functionality. TheInternet two-way data connection between the control PCB 27 and centralcomputer server 32 which hosts and operates a web-centric and/or mobileapp software application also empowers the owner of one or multiplecentral freezing machines 30 to remotely update one or more centralfreezing machine 30 software and settings and/or remotely control theoperation of one or more central freezing machines 30 and/or remotelyactivate and de-activate one or more central freezing machines 30 and/orhave immediate remote access to real time or historical statisticalinformation related to the repairs done by such machines, repairs perelectronic mobile device model, repairs per technician, repairs per timeperiod, repairs per location, repairs per grouped electronic mobiledevice models, technicians, time periods and locations, repair successrates, repair times, electronic mobile device models repaired,technician identity, defects of the central freezing machine 30, wrongcentral freezing machine 30 settings, user identified central freezingmachine 30 defects, consumables and parts required and being able toorder such consumables and parts immediately via the web-centric and/ora mobile app software application.

A communications PCB (printed circuit board) 28 is also shown. Personshaving skill in the art will realize that the communications PCB 28 canbe situated in different areas within the central freezing machine 30.The communications PCB 28 has an internal processor and modem which makethe communications PCB 28 capable of connecting to the Internet andtransfer data and commands to and from the control PCB 27 and thecentral computer server 32 via the Internet. The communications PCB 28gains access to the Internet via a wireless antenna 22 located on thebottom of the back panel 2 or from an Ethernet inlet port 25 alsolocated on the bottom of the back panel 2. Connection between thecommunications PCB 28 and a wireless Wi-Fi network is made possible viathe wireless antenna and a WPS (Wi-Fi Protected Setup) push button 33 aswell as by entering the wifi network password on the LCD/OLED display19.

A LCD/OLED display is also shown 19. The LCD/OLED display 19 is capableof displaying various operational information of the central freezingmachine 30 to the user of the central machine 30. The LCD/OLED display19 also has touch control allowing the user of the central freezingmachine 30 to input commands, change settings, perform software updates,connect the central freezing machine 30 to wireless networks and ingeneral to operate the central freezing machine 30.

A power inlet 23 is also shown. The power inlet 23 is located on thebottom of the back panel 2 and provides electrical power to the controlPCB 27, the communications PCB 28, the Stirling engine system 8 and theLCD/OLED display 19. An ON/OFF switch 26 is also located on the bottomof the back panel 2 and is utilized to power the central freezingmachine 30 in an on or off power position. An operations button 20located on the front panel 1 underneath the LCD/OLED display 19 is alsoshown. The operations button 20 is capable of making the centralfreezing machine 30 to perform various defined operations.

Turning now to FIG. 2A the adjustable cooling head ring fixture 9 andthe metal plate 10 shown in FIGS. 1A and 1B are shown. The adjustablecooling head ring fixture has four holes on a perimeter which match theexact location of four holes on the metal plate 10. Now turning to FIG.2B and FIG. 2C the adjustable cooling head ring fixture 9 and the metalplate 10 attached to each other are shown. Turning now to FIG. 2D andFIG. 2E the adjustable cooling head ring fixture 9, the Stirling engine8 cylindrical cooling head, the metal plate 10 and the Stirling engine 8with cylindrical cooling head shown in FIGS. 1A and 1B are also shown.The adjustable cooling head ring fixture 9 is affixed around theStirling engine 8 cylindrical cooling head and attached to suchadjustable cooling head ring fixture 9 is the metal plate 10 so that thesub-zero temperatures of the Stirling engine 8 cylindrical cooling headare transferred to the adjustable cooling head ring fixture 9 and to themetal plate 10 resulting in the metal plate 10 reaching sub-zerotemperatures and operating as a base upon which the electronic mobiledevice components/parts are placed in order to be frozen.

Turning now to FIG. 2F-2I, the Stirling engine 8 with cylindricalcooling head, the adjustable cooling head ring fixture 9, the metalplate 10, the encapsulation chamber 12, the freezing chamber 31, the tophousing panel 6, the bottom housing panel 5, the steel columns 7 and thepush down lid 14 with 5 layers 15, 16, 17, 18 are also shown. FIGS.2F-2I clearly show how the adjustable cooling head ring fixture 9 isaffixed around the Stirling engine 8 cylindrical cooling head andattached to such adjustable cooling head ring fixture 9 is the metalplate 10 so that the sub-zero temperatures of the Stirling engine 8cylindrical cooling head are transferred to the adjustable cooling headring fixture 9 and to the metal plate 10 resulting in the metal plate 10reaching sub-zero temperatures and operating as a base upon which theelectronic mobile device components/parts are placed in order to befrozen. FIGS. 2F-2I also clearly show how the encapsulation chamber 12encapsulates the Stirling engine 8 top end cylindrical cooling head, theadjustable cooling head ring fixture 9 and the metal plate 10 fortemperature and air insulation purposes and for strength and vibrationpurposes and also to form a freezing chamber 31 with the metal plate 10being the base of the freezing chamber 31.

Turning now to FIGS. 3A-3D the top housing panel 6, the freezing chamber31, the metal plate 10, the antenna 22 and the two adjustable leversystems 34 are shown. FIG. 3D clearly shows how the two adjustable leversystems are comprised of 3 parts, namely the adjustable lever screw 35,the main lever housing 36 and the adjustable press down panel 37. Asshown in FIGS. 3A-3D the main lever housing 36 slides within the leftand right grooves of the metal plate 10 and is also held down by suchgrooves. The mobile phone 38 is placed on the metal plate 10 and the twoadjustable lever systems 34 are moved into position so that theadjustable press down panels 37 of each adjustable lever system 34 areabove the top end and bottom end of the mobile phone 38. Thereafter theadjustable lever screw 35 is turned in a clockwise direction resultingin the adjustable press down panels 37 being pushed downwards onto themobile phone slowly applying pressure so that the mobile phone is firmlypressed against the metal plate 10 so as to maximize contact between themobile phone 38 and the metal plate 10 lessening the freezing period,ensuring uniform freezing and also to maximize the freezing efficiency.

Reference has been made to the examples illustrated in the drawings andspecific language was used herein to describe the same. It willnevertheless be understood that no limitation of the scope of thetechnology is thereby intended. Alterations and further modifications ofthe features illustrated herein and additional applications of theexamples as illustrated herein are to be considered within the scope ofthe description.

Furthermore, the described features, structures, or characteristics maybe combined in any suitable manner in one or more examples. In thepreceding description, numerous specific details were provided, such asexamples of various configurations to provide a thorough understandingof examples of the described technology. It will be recognized, however,that the technology may be practiced without one or more of the specificdetails, or with other methods, components, devices, etc. In otherinstances, well-known structures or operations are not shown ordescribed in detail to avoid obscuring aspects of the technology.

Although the subject matter has been described in language specific tostructural features and/or operations, it is to be understood that thesubject matter defined in the appended claims is not necessarily limitedto the specific features and operations described above. Rather, thespecific features and acts described above are disclosed as exampleforms of implementing the claims. Numerous modifications and alternativearrangements may be devised without departing from the spirit and scopeof the described technology.

1. A system for freezing components/parts of electronic mobile devices,comprising: a housing, said housing containing: an engine; an adjustablemetal cooling head ring fixture affixed on to a cylindrical cooling headof the engine; a metal plate attached to the adjustable metal coolinghead ring fixture so that sub-zero temperatures of the cylindricalcooling head of the engine are transferred to the adjustable metalcooling head ring fixture and to the metal plate resulting in the metalplate reaching sub-zero temperatures and operating as a base upon whichthe electronic mobile device components/parts are placed in order to befrozen; an encapsulation chamber for encapsulating the cylindricalcooling head of the engine, the adjustable metal cooling head ringfixture and the metal plate for temperature and air insulation purposes,for strength and vibration absorption purposes and also for forming afreezing chamber with the metal plate being the base of the freezingchamber; a push down lid for sealing the freezing chamber and also forpushing the electronic mobile device parts/components firmly down on asurface of the metal plate; a control printed circuit board withprocessor and software capable of controlling the operation of theengine; a power inlet utilized to provide power to the control printedcircuit board and to the engine; and an on/off switch for powering thesystem on and off.
 2. The system of claim 1, further comprising anLCD/OLED display panel for displaying information regarding theoperation of the system and for operating the system.
 3. The system ofclaim 1, further comprising four or more push down clips found on eachcorner of the push down lid and which allow the push down lid to closewhen pushed down, and when pushed down again to pop open.
 4. The systemof claim 3, further comprising the push down lid with four additionallayers of expanded polypropylene, sponge polyurethane, polyurethane andexpanded polypropylene for creating a sponge spring effect for the pushdown lock and unlock feature of the push down lid and also for applyinggentle firm downwards pressure on the electronic mobile device part forefficient contact with a metal base of the freezing chamber.
 5. Thesystem of claim 1, further comprising the push down lid with four ormore additional layers of expanded polypropylene, sponge polyurethane,polyurethane and expanded polypropylene for creating a sponge springeffect for applying gentle firm downwards pressure on the electronicmobile device part for efficient contact with a metal base of thefreezing chamber.
 6. The system of claim 1, further comprising a wallperimeter placed within the freezing chamber created by theencapsulation chamber.
 7. The system of claim 1, further comprising anEthernet inlet port, a Wi-Fi antenna, a WPS switch and a communicationsprinted circuit board with processor and operating system software forenabling two-way data and command transfer between the control printedcircuit board and a central computer server via the Internet to enableremote system operation and system software updating via the centralcomputer server.
 8. The system of claim 7, further comprising a centralcomputer server and a web-centric and/or mobile app software applicationhosted and operated on the central computer server which connects via atwo-way data transmission connection with the control printed circuitboard using the communications printed circuit board and the Internet,facilitating real time, remote sending and receiving of operatinginstructions, freezing parameters (temperature, time) and data specificto a particular mobile device and/or mobile device component/part aswell as facilitating remote system software updates as well asempowering a user of the system to operate the system via theweb-centric and/or mobile app software application hosted and operatedon the central computer server and to obtain real time and historicoperational data of the system.
 9. The system of claim 1, furthercomprising a push operation button for making the system perform certainfunctions.
 10. The system of claim 1, further comprising a secondaryprinted circuit board for controlling various functions of the engine,an internal power supply for supplying a varying range of voltage andamperage to the engine and a cooling fan for cooling the engine, allassembled together with the engine to form a single component.
 11. Thesystem of claim 10, further comprising a display panel for displayinginformation regarding the operation of the system as well as foroperating the system.
 12. The system of claim 11, further comprisingfour or more push down clips found on each corner of the push down lidand which allow the push down lid to close when pushed down, and whenpushed down again to pop open.
 13. The system of claim 12, furthercomprising the push down lid with four additional layers of expandedpolypropylene, sponge polyurethane, polyurethane and expandedpolypropylene for creating a sponge spring effect required for the pushdown lock and unlock feature of the push down lid and also for applyinggentle firm downwards pressure on the electronic mobile device part forefficient contact with a metal base of the freezing chamber.
 14. Thesystem of claim 13, further comprising a wall perimeter placed withinthe freezing chamber created by the encapsulation chamber.
 15. Thesystem of claim 14, further comprising further comprising an Ethernetinlet port, a Wi-Fi antenna, a WPS switch and a communications printedcircuit board for enabling two way data and command transfer between thecontrol printed circuit board and a central computer server via theInternet to enable remote system operation and system software updatingvia the central computer server.
 16. The system of claim 15, furthercomprising a central computer server and a web-centric and/or mobile appsoftware application hosted and operated on the central computer serverwhich connects via a two-way data transmission connection with thecontrol printed circuit board using the communications printed circuitboard and the Internet, facilitating real time, remote sending andreceiving of operating instructions, freezing parameters (temperature,time) and data specific to a particular mobile device and/or mobiledevice component/part as well as facilitating remote system softwareupdates as well as empowering a user of the system to operate the systemvia the web-centric and/or mobile app software application hosted andoperated on the central computer server and to obtain real time andhistoric operational data of the system.